See also Galton Height Dataset and Pearson Height Dataset
Anthropometry is the measurement and study of the physical proportions and functional capabilities of the human body. The name is derived from the Greek word anthros (“man”) and metron (“measure”). The contemporary field of ergonomics (also known as human factors) explicitly considers anthropometric principles in the design of many products, processes, and systems intended for use by people (e.g., clothing, furniture, medical devices, hand tools, keyboards, vehicles). There are many important applications in the area of safety, including crash test dummies. Crime scene investigators, pathologists, historians, and forensic anthropologists also make extensive use of anthropometric measurements. The related term craniometry refers to measurements of the cranium (skull).
Belgian scholar Adolphe Quetelet (1796-1874) was a pioneer in anthopometry. Among his many pursuits, which included investigations in the disciplines later known as sociology and criminology, he was interested in the quantification of what he referred to as l’homme moyen (“the average man”). His measurements helped to demonstrate the natural distribution and variability of various aspects of the human body, like height and weight, both of which he believed followed a bell-shaped curve (i.e., normal distribution). The measure we now call Body Mass Index (BMI) was developed by Quetelet sometime between 1830 and 1850.
Although he was among the first to approach anthropometrics in a systematic manner, Quetelet was certainly not the first person to theorize about human measurements. Roman architect and engineer Vitruvius (approximately 80 BC-15 BC) wrote Ten Books on Architecture (circa 20 BC), which is one of the most important sources of information on Roman building methods. It also included his thoughts about the proportionality of the human body and how these geometric features relate to divinity and the ideal design of man-made structures. He suggested (among other things) that people are squares: “the length of the outspread arms is equal to the height of a man”. Other statements include “the length of the hand is one-tenth of the height of a man” and “from below the foot to below the knee is a quarter of the height of a man.” Some of these ideas were illustrated by Leonardo da Vinci (1452-1590) in his famous pen-and-ink drawing “The Vitruvian Man” (~1490 AD). In 2008, Time magazine published a picture of Olympic medalist Michael helps in a Vitruvian Man pose to illustrate what some call his “freakish physique”, a term that has also applied been to surfer Owen Wright (the video above “Our friends at Indoek…” might be slow to load).
The anthropometric data here were collected from students in Dr. Thomley’s STT1810 and STT3850 courses at Appalachian State University.
Rows: 547
Columns: 9
$ gender <chr> "female", "female", "female", "female", "female", "female", "…
$ ideal <dbl> 64, 64, 65, 63, 68, 64, NA, 65, 66, 63, 62, 60, 65, 68, 64, 6…
$ height <dbl> 59.75, 59.75, 60.00, 60.00, 60.00, 60.00, 60.50, 60.50, 61.00…
$ armspan <dbl> 58.5, 58.5, 61.0, 58.0, 62.0, 60.0, 60.0, 61.5, 63.0, 59.0, 6…
$ forearm <dbl> 15.00, 15.00, 16.00, 15.00, 15.00, 15.00, 15.50, 15.00, 16.50…
$ hand <dbl> 6.50, 6.50, 7.00, 6.25, 6.00, 6.00, 5.50, 7.00, 7.00, 6.00, 6…
$ leg <dbl> 16.00, 16.00, 16.00, 16.25, 18.00, 16.00, 17.75, 16.50, 19.00…
$ foot <dbl> 8.50, 8.50, 8.50, 9.50, 9.00, 8.00, 8.50, 8.50, 9.50, 8.75, 8…
$ semester <chr> "F15", "F15", "F13", "F15", "S13", "Sum13", "S14", "Sum14", "…
# A tibble: 6 × 9
gender ideal height armspan forearm hand leg foot semester
<chr> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <chr>
1 female 64 59.8 58.5 15 6.5 16 8.5 F15
2 female 64 59.8 58.5 15 6.5 16 8.5 F15
3 female 65 60 61 16 7 16 8.5 F13
4 female 63 60 58 15 6.25 16.2 9.5 F15
5 female 68 60 62 15 6 18 9 S13
6 female 64 60 60 15 6 16 8 Sum13
Rows: 150
Columns: 6
$ maxbreadth <dbl> 131, 125, 131, 119, 136, 138, 139, 125, 131, 134, 129, 1…
$ basibregmatic <dbl> 138, 131, 132, 132, 143, 137, 130, 136, 134, 134, 138, 1…
$ basialveolar <dbl> 89, 92, 99, 96, 100, 89, 108, 93, 102, 99, 95, 95, 109, …
$ nasalht <dbl> 49, 48, 50, 44, 54, 56, 48, 48, 51, 51, 50, 53, 51, 50, …
$ time1 <dbl> -4000, -4000, -4000, -4000, -4000, -4000, -4000, -4000, …
$ time2 <chr> "BCE.4000", "BCE.4000", "BCE.4000", "BCE.4000", "BCE.400…
# A tibble: 6 × 6
maxbreadth basibregmatic basialveolar nasalht time1 time2
<dbl> <dbl> <dbl> <dbl> <dbl> <chr>
1 131 138 89 49 -4000 BCE.4000
2 125 131 92 48 -4000 BCE.4000
3 131 132 99 50 -4000 BCE.4000
4 119 132 96 44 -4000 BCE.4000
5 136 143 100 54 -4000 BCE.4000
6 138 137 89 56 -4000 BCE.4000
Thomson, Arthur and Randall-MacIver, David. (1905). Ancient Races of the Thebaid. Oxford: Oxford University Press.